CN113197780A - Stirring type scutellaria baicalensis decocting equipment capable of removing impurities without water and decocting method thereof - Google Patents

Abstract

The invention relates to the field of medicine production, in particular to stirring type scutellaria baicalensis decocting equipment capable of realizing anhydrous impurity removal and a decocting method thereof. The technical problem of the invention is that: provides stirring type scutellaria baicalensis decocting equipment capable of realizing anhydrous impurity removal and a decocting method thereof. The technical scheme is as follows: a stirring type scutellaria baicalensis decocting device capable of realizing anhydrous impurity removal comprises a support frame, a first collecting box, a control screen, an impurity removal system, a crushing system and a mixing system; the support frame is connected with the hybrid system to the hybrid system is connected with crushing system. The invention can remove sundries on the surface of the scutellaria baicalensis without water, collect the sundries, crush the scutellaria baicalensis in multiple stages to obtain the scutellaria baicalensis powder, and fully contact the scutellaria baicalensis with water by continuously stirring the mixed liquid of the scutellaria baicalensis powder and the water during decoction, so that the effective ingredients of the scutellaria baicalensis are mixed with the water to be fully utilized, and the equipment has high automation degree.

Description

Stirring type scutellaria baicalensis decocting equipment capable of removing impurities without water and decocting method thereof

Technical Field

The invention relates to the field of medicine production, in particular to stirring type scutellaria baicalensis decocting equipment capable of realizing anhydrous impurity removal and a decocting method thereof.

Background

The scutellaria baicalensis and the active ingredients thereof have the inhibiting effect on various viruses. In the aspect of improving the immunity of the organism, the scutellaria has good regulating function, and not only has the function of enhancing the low immunity but also has the function of regulating in two directions.

In the prior art, when the scutellaria baicalensis is processed to prepare a medicament, a decoction liquid of the scutellaria baicalensis is required to be obtained, a large amount of dust and a large amount of scraps are adhered to the outer surface of the scutellaria baicalensis before the scutellaria baicalensis is used, the conventional treatment mode is usually water washing or manual scrubbing, so that manual operation is required, the cleaning effect is not high, and the scutellaria baicalensis is required to be used in time after being soaked in water, so that certain limitation is realized; the scutellaria baicalensis needs to be crushed before decoction, the conventional crushing is only to throw the scutellaria baicalensis into a crushing device for crushing, and the particles of the astragalus membranaceus have different sizes, so that the decoction time cannot be accurately controlled during decoction; in the existing decocting method, when the decoction liquid is separated from the scutellaria baicalensis, filtration is carried out through a filtering device, so that a large amount of scutellaria baicalensis crushed slag still exists in the obtained decoction liquid, meanwhile, the scutellaria baicalensis needs to be transferred for many times, so that a large amount of time is wasted, and meanwhile, when the scutellaria baicalensis is decocted, the scutellaria baicalensis is deposited at the bottom of the decocting device, so that part of the scutellaria baicalensis is not fully contacted with water, and the effective components cannot be effectively extracted.

In combination with the above problems, we propose a stirring type scutellaria decocting device and a decocting method thereof which can realize anhydrous impurity removal, so as to overcome the above problems.

Disclosure of Invention

In order to overcome the defects that in the prior art, when the scutellaria baicalensis is processed to prepare a medicament, a decoction liquid of the scutellaria baicalensis is required to be obtained, a large amount of dust and a large amount of scraps are adhered to the outer surface of the scutellaria baicalensis before the scutellaria baicalensis is used, the conventional treatment mode is usually water washing or manual scrubbing, so manual operation is required, the cleaning effect is not high, and the scutellaria baicalensis is required to be used in time after being soaked in water, so that certain limitation is caused; the scutellaria baicalensis needs to be crushed before decoction, the conventional crushing is only to throw the scutellaria baicalensis into a crushing device for crushing, and the particles of the astragalus membranaceus have different sizes, so that the decoction time cannot be accurately controlled during decoction; the invention discloses a method for decocting scutellaria baicalensis, which is characterized in that when scutellaria baicalensis is decocted, multiple times of decoction are needed to extract active ingredients of scutellaria baicalensis, the decoction liquid and the scutellaria baicalensis are separated by a filtering device in the conventional decocting method, so that a large amount of scutellaria baicalensis crushed slag still exists in the obtained decoction liquid, and the scutellaria baicalensis needs to be transferred for multiple times, so that a large amount of time is wasted, and meanwhile, when the scutellaria baicalensis is decocted, the scutellaria baicalensis is deposited at the bottom of the decocting device, so that part of the scutellaria baicalensis is not fully contacted with water, and the active ingredients cannot be effectively extracted, and the technical problem of the invention is as follows: provides stirring type scutellaria baicalensis decocting equipment capable of realizing anhydrous impurity removal and a decocting method thereof.

The technical scheme is as follows: a stirring type scutellaria baicalensis decocting device capable of realizing anhydrous impurity removal comprises a support frame, a first collecting box, a control screen, an impurity removal system, a crushing system and a mixing system; the supporting frame is connected with the first collecting box; the support frame is connected with an impurity removal system; the support frame is connected with the crushing system; the support frame is connected with a mixing system, and the mixing system is connected with a crushing system; the first collecting box is connected with the control screen.

More preferably, the impurity removing system comprises an impurity removing hopper, a connecting rod, a cylinder, a first electric push rod, a first connecting plate, a first motor, a disc, a push plate, a polish rod, a spring, an excavating hole plate, a brushing plate, a second connecting plate, a second collecting box, a first electric slide rail, a first electric slide block, a first connecting frame, an isolating baffle, a third connecting plate, an air supply box, a second electric slide rail, a second electric slide block, a second connecting frame, a first L-shaped baffle, a third electric slide rail, a third electric slide block, an L-shaped connecting plate, a fourth connecting plate and a limiting cylinder; two sides of the impurity removing hopper are respectively hinged with the two groups of connecting rods, and the lower parts of the two groups of connecting rods are fixedly connected with the supporting frame; two sides of the impurity removing hopper are respectively hinged with the two groups of cylinders, and the lower parts of the two groups of cylinders are hinged with the supporting frame; the impurity removing hopper is fixedly connected with the four groups of first electric push rods in sequence; the four groups of first electric push rods are respectively positioned in four directions of the impurity removing hopper; the four groups of first electric push rods are fixedly connected with the first connecting plate in sequence; the first connecting plate is connected with a first motor; the output shaft of the first motor is fixedly connected with the disc; the disc is contacted with the push plate; the side surface of the push plate is fixedly connected with the polish rod; the lower part of the push plate is fixedly connected with the bristle plate; a spring is arranged on the outer side of the polish rod and fixedly connected with the push plate; the spring is fixedly connected with the hole digging plate, the upper part of the hole digging plate is fixedly connected with the first connecting plate, and the hole digging plate is in sliding connection with the polish rod; the brushing plate is positioned above the impurity removing hopper; one side of the impurity removing hopper is connected with the two groups of second connecting plates through bolts; the other side of the impurity removing hopper is connected with two groups of third connecting plates through bolts; the two groups of second connecting plates are respectively in bolted connection with two sides of the second collecting box, and the second collecting box is in mutual contact with the impurity removing hopper; two groups of first electric slide rails are fixedly connected with two sides of the impurity removing hopper respectively; the two groups of first electric slide rails are respectively connected with the two groups of first electric slide blocks in a sliding manner; two groups of first electric slide blocks are fixedly connected with two sides of the first connecting frame respectively; the first connecting frame is in bolted connection with the isolating baffle, and the isolating baffle is in sliding connection with the impurity removing hopper; the two groups of third connecting plates are fixedly connected with two sides of the air supply box respectively, and the air supply box is in contact with the impurity removal hopper; two groups of second electric slide rails are fixedly connected with two sides of the impurity removing hopper respectively; the two groups of second electric slide rails are sequentially in sliding connection with the two groups of second electric slide blocks; two groups of second electric sliding blocks are fixedly connected with two sides of the second connecting frame respectively; the second connecting frame is in bolted connection with the first L-shaped baffle, and the first L-shaped baffle is in sliding connection with the impurity removing hopper; the third electric slide rail is fixedly connected with the side surface of the impurity removing hopper; the third electric slide rail is in sliding connection with the third electric slide block; the third electric sliding block is fixedly connected with the L-shaped connecting plate; four groups of third electric sliding rails, third electric sliding blocks and L-shaped connecting plates are arranged, and the four groups of third electric sliding rails, the four groups of third electric sliding blocks and the four groups of L-shaped connecting plates are respectively positioned in four directions of the impurity removing hopper; the four groups of L-shaped connecting plates are sequentially connected with four corners below the fourth connecting plate through bolts; and the upper part of the fourth connecting plate is fixedly connected with the limiting cylinder, and the limiting cylinder is spliced with the impurity removing hopper.

More preferably, the crushing system comprises a bracket, a first driving wheel, a first rotating rod, a second driving wheel, a third driving wheel, a round roller, an arc-shaped cutter, a round table, a serrated plate, a grinding column, a second electric push rod, a second L-shaped baffle, an air inlet pipe, a feed inlet, a grinding cabin and a first connecting pipe; the bracket is fixedly connected with the support frame; the first driving wheel is connected with the mixing system; the bracket is rotationally connected with the first rotating rod; the first rotating rod is fixedly connected with the first driving wheel and the second driving wheel in sequence; the outer ring surface of the second driving wheel is in transmission connection with a third driving wheel through a belt; the third driving wheel is fixedly connected with the round roller; four groups of arc-shaped cutters are arranged on the outer surface of the round roller; the lower part of the round roller is fixedly connected with the round table; the outer surface of the circular truncated cone is fixedly connected with fifteen groups of sawtooth plates in sequence; the lower part of the circular truncated cone is fixedly connected with the grinding column; one side of the second electric push rod is fixedly connected with the bracket, and the other side of the second electric push rod is fixedly connected with the second L-shaped baffle; the second L-shaped baffle is fixedly connected with the air inlet pipe; the second L-shaped baffle is contacted with the feed inlet; the lower part of the feeding hole is fixedly connected with the grinding cabin, the grinding cabin is rotatably connected with the round roller, and the lower part of the grinding cabin is fixedly connected with the support frame; the grinding cabin is fixedly connected with a first connecting pipe, and the first connecting pipe is connected with the mixing system.

More preferably, the mixing system comprises a second motor, a fourth transmission wheel, a fifth transmission wheel, a sixth transmission wheel, a telescopic rod, a seventh transmission wheel, a fifth connecting plate, a third electric push rod, a fourth electric push rod, an eighth transmission wheel, a second rotating rod, a mixing cabin, a water inlet, a hollow block, a second connecting pipe, a water pump, a third connecting pipe, a C-shaped plate, a shifting plate and a filter screen; the second motor is connected with the support frame; an output shaft of the second motor is fixedly connected with the fourth driving wheel and the fifth driving wheel in sequence; the outer ring surface of the fifth driving wheel is in transmission connection with the first driving wheel through a belt; the outer ring surface of the fourth driving wheel is in transmission connection with the sixth driving wheel through a belt; the sixth driving wheel is fixedly connected with the telescopic rod, and the telescopic rod is rotatably connected with the support frame; the telescopic rod is fixedly connected with the seventh driving wheel; the outer surface of the telescopic rod is rotatably connected with the fifth connecting plate; two sides below the fifth connecting plate are fixedly connected with the third electric push rod and the fourth electric push rod in sequence, and the lower parts of the third electric push rod and the fourth electric push rod are fixedly connected with the supporting frame; the outer ring surface of the seventh driving wheel is in transmission connection with the eighth driving wheel through a belt; the eighth transmission wheel is fixedly connected with the second rotating rod, and the second rotating rod is rotatably connected with the fifth connecting plate; the second rotating rod is connected with the mixing cabin in a sliding mode, the lower portion of the mixing cabin is fixedly connected with the supporting frame, and the mixing cabin is connected with the first connecting pipe; the upper part of the mixing cabin is fixedly connected with the water inlet; the side surface of the mixing cabin is fixedly connected with the hollow block; the hollow block is fixedly connected with the second connecting pipe; the second connecting pipe is fixedly connected with the water pump, and the water pump is connected with the support frame through bolts; the water pump is fixedly connected with the third connecting pipe, and the third connecting pipe is fixedly connected with the first collecting box; the lower part of the second rotating rod is fixedly connected with the C-shaped plate; two sides of the C-shaped plate are fixedly connected with the two groups of shifting plates respectively; the lower part of the C-shaped plate is fixedly connected with the filter screen, and the outer surface of the filter screen is contacted with the interior of the mixing cabin.

More preferably, an air outlet is arranged at one side of the air supply box close to the second collection box, and the air supply direction of the air outlet is inclined downwards.

More preferably, the first L-shaped baffle is composed of a vertical plate and an inclined plate.

More preferably, an arc transition is arranged above the limiting cylinder.

More preferably, when viewed from the top, the four groups of arc-shaped cutters are fixedly connected to the outer surface of the round roller in a surrounding manner, wherein two groups of arc-shaped cutters are fixedly connected to the upper half part of the round roller, and the other two groups of arc-shaped cutters are fixedly connected to the lower half part of the round roller.

More preferably, a filter screen is arranged on one side of the hollow block close to the mixing cabin.

A stirring type scutellaria baicalensis decocting method capable of realizing anhydrous impurity removal comprises the following working steps:

the method comprises the following steps: impurity removal, namely putting the scutellaria baicalensis into an impurity removal system, scrubbing the surface of the scutellaria baicalensis in a closed space to separate impurities, and simultaneously blowing air to discharge and collect the impurities separated from the surface of the scutellaria baicalensis;

step two: transferring, namely transferring the scutellaria baicalensis into a crushing system through an inclined impurity removal system;

step three: crushing, and performing multistage crushing on the scutellaria baicalensis by a crushing system to obtain scutellaria baicalensis powder;

step four: transferring, namely transferring the scutellaria baicalensis powder in the step III into a mixing system;

step five: mixing, namely adding water into a mixing system and stirring to obtain a mixed solution;

step six: decocting, namely heating the mixed liquid in the fifth step to obtain a decoction;

step seven: separating and transferring, namely filtering the decoction in the step six, transferring the decoction into a first collecting box for collection, and only remaining scutellaria residues in a mixing system;

step eight: stirring, namely stirring the residual scutellaria baicalensis residue in the seventh step by a mixing system;

step nine: and (3) carrying out secondary decoction and tertiary decoction, repeating the step five to the step eight twice, and meanwhile, fully mixing the decoction obtained by the primary decoction, the decoction obtained by the secondary decoction and the decoction obtained by the tertiary decoction in a first collection box to obtain a mixed decoction.

Compared with the prior art, the invention has the following advantages:

(1) in order to solve the problems that in the prior art, when the scutellaria baicalensis is processed to prepare a medicament, a decoction liquid of the scutellaria baicalensis is required to be obtained, a large amount of dust and a large amount of scraps are adhered to the outer surface of the scutellaria baicalensis before the scutellaria baicalensis is used, the conventional treatment mode is usually water washing or manual scrubbing, so manual operation is required, the cleaning effect is not high, and the scutellaria baicalensis is required to be used in time after being soaked in water, so that certain limitation is caused; the scutellaria baicalensis needs to be crushed before decoction, the conventional crushing is only to throw the scutellaria baicalensis into a crushing device for crushing, and the particles of the astragalus membranaceus have different sizes, so that the decoction time cannot be accurately controlled during decoction; the method is characterized in that when the scutellaria baicalensis is decocted, multiple times of decoction are needed to extract effective components of the scutellaria baicalensis, the decoction liquid and the scutellaria baicalensis are separated by filtering equipment in the conventional decoction method, so that a large amount of scutellaria baicalensis crushed slag still exists in the decoction liquid, the scutellaria baicalensis needs to be transferred for multiple times, a large amount of time is wasted, and meanwhile, when the scutellaria baicalensis is decocted, the scutellaria baicalensis is deposited at the bottom of the decoction equipment, so that part of the scutellaria baicalensis is not fully contacted with water, and the effective components cannot be effectively extracted.

(2) Design the edulcoration system, crushing system and hybrid system, when using, get rid of the debris on scutellaria baicalensis surface through the edulcoration system, collect debris together simultaneously, then the edulcoration system shifts during clean scutellaria baicalensis to crushing system, crushing system smashes the scutellaria baicalensis into powdered and shifts to the hybrid system in, inject proper amount water into the hybrid system, let the scutellaria baicalensis powder fully contact with water fully and decoct, the decocte liquid that will obtain shifts to first collecting box and collects, carry out twice decocte once more to the scutellaria baicalensis sediment that obtains after decocting once afterwards and let whole decocte liquid at first collecting box intensive mixing, and then from obtaining mixed decocte liquid.

(3) The scutellaria baicalensis powder decocting device has the advantages that impurities on the surfaces of the scutellaria baicalensis can be removed in an anhydrous mode, the impurities are collected, the scutellaria baicalensis is subjected to multi-stage crushing, the scutellaria baicalensis powder is obtained, the scutellaria baicalensis is fully contacted with water through constantly stirring mixed liquid of the scutellaria baicalensis powder and the water during decocting, so that the active ingredients of the scutellaria baicalensis are mixed with the water to be fully utilized, and the automation degree of the device is high.

Drawings

FIG. 1 is a schematic perspective view of a first embodiment of the present invention;

FIG. 2 is a schematic perspective view of a second embodiment of the present invention;

FIG. 3 is a schematic view of a first three-dimensional structure of the impurity removal system according to the present invention;

FIG. 4 is a schematic view of a second three-dimensional structure of the trash removal system of the present invention;

FIG. 5 is a schematic view of a first partial perspective structure of the impurity removal system of the present invention;

FIG. 6 is a schematic view of a second partial perspective structure of the trash removal system of the present disclosure;

FIG. 7 is a schematic view of a third partial perspective structure of the trash removal system of the present disclosure;

FIG. 8 is a schematic view of a fourth partial perspective structure of the trash removal system of the present disclosure;

FIG. 9 is a schematic view of a fifth partial perspective structure of the trash removal system of the present disclosure;

FIG. 10 is a schematic view of a sixth partial perspective view of the trash removal system of the present disclosure;

FIG. 11 is a schematic view of a seventh partial perspective structure of the trash removal system of the present disclosure;

FIG. 12 is a schematic view of an eighth partial perspective structure of the trash removal system of the present disclosure;

FIG. 13 is a schematic perspective view of the pulverizing system of the present invention;

FIG. 14 is a schematic view of a partial perspective view of the pulverizing system of the present invention;

FIG. 15 is a schematic perspective view of a mixing system of the present invention;

FIG. 16 is a partial perspective view of the mixing system of the present invention.

The parts are labeled as follows: 1. a support frame, 2, a first collecting box, 3, a control screen, 4, an impurity removing system, 5, a crushing system, 6, a mixing system, 401, an impurity removing hopper, 402, a connecting rod, 403, a cylinder, 404, a first electric push rod, 405, a first connecting plate, 406, a first motor, 407, a disc, 408, a push plate, 409, a polished rod, 410, a spring, 411, an excavating plate, 412, a disc plate, 413, a second connecting plate, 414, a second collecting box, 415, a first electric slide rail, 416, a first electric slide block, 417, a first connecting frame, 418, an isolation baffle, 419, a third connecting plate, 420, an air supply box, 421, a second electric slide rail, 422, a second electric slide block, 423, a second connecting frame, 424, a first L-shaped baffle, 425, a third electric slide rail, 426, a third electric slide block, 427, an L-shaped connecting plate, 428, a fourth connecting plate, 429, a limiting cylinder, 501 and a support, 502. the grinding machine comprises a first transmission wheel, 503, a first rotating rod, 504, a second transmission wheel, 505, a third transmission wheel, 506, a round roller, 507, an arc-shaped cutter, 508, a round table, 509, a sawtooth plate, 510, a grinding column, 511, a second electric push rod, 512, a second L-shaped baffle plate, 513, an air inlet pipe, 514, a feed inlet, 515, a grinding cabin, 516, a first connecting pipe, 601, a second motor, 602, a fourth transmission wheel, 603, a fifth transmission wheel, 604, a sixth transmission wheel, 605, a telescopic rod, 606, a seventh transmission wheel, 607, a fifth connecting plate, 608, a third electric push rod, 609, a fourth electric push rod, 610, an eighth transmission wheel, 611, a second rotating rod, 612, a mixing cabin, 613, a water inlet, 614, a hollow block, 615, a second connecting pipe, 616, a water pump, 617, a third connecting pipe, 618, C, 619, a shifting plate, 620 and a filter screen.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

A stirring type radix Scutellariae decocting device capable of removing impurities without water is shown in fig. 1-16, and comprises a support frame 1, a first collecting box 2, a control screen 3, an impurity removing system 4, a pulverizing system 5 and a mixing system 6; the support frame 1 is connected with the first collecting box 2; the support frame 1 is connected with an impurity removal system 4; the support frame 1 is connected with a crushing system 5; the support frame 1 is connected with a mixing system 6, and the mixing system 6 is connected with a crushing system 5; the first collecting tank 2 is connected with a control panel 3.

The working principle is as follows: when the equipment is used, the equipment is horizontally placed at a place to be used, a power supply and a water source are externally connected, a blower is externally connected, the scutellaria baicalensis prepared for preparing a medicine is placed into the equipment, then a control screen 3 is opened to control the operation of the equipment, firstly, impurities on the surface of the scutellaria baicalensis are removed through an impurity removal system 4, meanwhile, the impurities are collected together, then, the clean scutellaria baicalensis is transferred into a crushing system 5 through the impurity removal system 4, the scutellaria baicalensis is crushed into powder by the crushing system 5 and transferred into a mixing system 6, a proper amount of water is injected into the mixing system 6, the scutellaria baicalensis powder can be fully contacted with the water and decocted, the obtained decoction liquid is transferred into a first collection box 2 to be collected, then, the scutellaria baicalensis dregs obtained after decoction once are decocted for two times again, all the decoction liquid is fully mixed in the first collection box 2, and then the mixed decoction liquid, the method has the advantages that impurities on the surface of the scutellaria baicalensis can be removed without water, the impurities are collected, the scutellaria baicalensis is subjected to multi-stage crushing to obtain the scutellaria baicalensis powder, the scutellaria baicalensis is fully contacted with water by continuously stirring mixed liquid of the scutellaria baicalensis powder and the water during decoction, so that the effective components of the scutellaria baicalensis are mixed with the water to be fully utilized, and the automation degree of equipment is high.

The impurity removing system 4 comprises an impurity removing hopper 401, a connecting rod 402, a cylinder 403, a first electric push rod 404, a first connecting plate 405, a first motor 406, a disc 407, a push plate 408, a polish rod 409, a spring 410, an excavating hole plate 411, a bristle plate 412, a second connecting plate 413, a second collecting box 414, a first electric slide rail 415, a first electric slide block 416, a first connecting frame 417, an isolation baffle 418, a third connecting plate 419, an air supply box 420, a second electric slide rail 421, a second electric slide block 422, a second connecting frame 423, a first L-shaped baffle 424, a third electric slide rail 425, a third electric slide block 426, an L-shaped connecting plate 427, a fourth connecting plate 428 and a limiting cylinder 429; the two sides of the impurity removing hopper 401 are respectively hinged with the two groups of connecting rods 402, and the lower parts of the two groups of connecting rods 402 are fixedly connected with the supporting frame 1; two sides of the impurity removing hopper 401 are respectively hinged with the two groups of cylinders 403, and the lower parts of the two groups of cylinders 403 are hinged with the support frame 1; the impurity removing hopper 401 is fixedly connected with four groups of first electric push rods 404 in sequence; the four groups of first electric push rods 404 are respectively positioned at four positions of the impurity removing hopper 401; the four groups of first electric push rods 404 are fixedly connected with the first connecting plate 405 in sequence; the first connection plate 405 is connected with a first motor 406; the output shaft of the first motor 406 is fixedly connected with the disc 407; the disk 407 and the push plate 408 contact each other; the side surface of the push plate 408 is fixedly connected with the polish rod 409; the lower part of the push plate 408 is fixedly connected with the bristle plate 412; a spring 410 is arranged on the outer side of the polish rod 409, and the spring 410 is fixedly connected with the push plate 408; the spring 410 is fixedly connected with the hole digging plate 411, the upper part of the hole digging plate 411 is fixedly connected with the first connecting plate 405, and the hole digging plate 411 is connected with the polish rod 409 in a sliding way; the bristle plate 412 is positioned above the trash hopper 401; one side of the impurity removing hopper 401 is in bolt connection with the two groups of second connecting plates 413; the other side of the impurity removing hopper 401 is in bolt connection with two groups of third connecting plates 419; two groups of second connecting plates 413 are respectively in bolt connection with two sides of the second collecting box 414, and the second collecting box 414 is in contact with the impurity removing hopper 401; two groups of first electric slide rails 415 are fixedly connected with two sides of the impurity removing hopper 401 respectively; the two groups of first electric slide rails 415 are respectively connected with the two groups of first electric slide blocks 416 in a sliding manner; two groups of first electric sliding blocks 416 are fixedly connected with two sides of the first connecting frame 417 respectively; the first connecting frame 417 is in bolt connection with the isolation baffle 418, and the isolation baffle 418 is in sliding connection with the impurity removing hopper 401; two groups of third connecting plates 419 are fixedly connected with two sides of the air supply box 420 respectively, and the air supply box 420 is in contact with the impurity removing hopper 401; two groups of second electric slide rails 421 are respectively fixedly connected with two sides of the impurity removing hopper 401; the two groups of second electric slide rails 421 are sequentially connected with the two groups of second electric slide blocks 422 in a sliding manner; two groups of second electric sliding blocks 422 are fixedly connected with two sides of the second connecting frame 423 respectively; the second connecting frame 423 is connected with the first L-shaped baffle 424 through bolts, and the first L-shaped baffle 424 is connected with the impurity removing hopper 401 in a sliding mode; the third electric slide rail 425 is fixedly connected with the side surface of the impurity removing hopper 401; the third electric slide rail 425 is connected with the third electric slide block 426 in a sliding manner; the third electric sliding block 426 is fixedly connected with the L-shaped connecting plate 427; four groups of third electric sliding rails 425, third electric sliding blocks 426 and L-shaped connecting plates 427 are arranged, and the four groups of third electric sliding rails 425, third electric sliding blocks 426 and L-shaped connecting plates 427 are respectively positioned at four positions of the impurity removing hopper 401; four sets of L-shaped connecting plates 427 are sequentially in bolted connection with the four corners below the fourth connecting plate 428; the upper part of the fourth connecting plate 428 is fixedly connected with a limiting cylinder 429, and the limiting cylinder 429 is inserted into the impurity removing hopper 401.

When the device is used, firstly, the scutellaria baicalensis is placed into the impurity removing hopper 401, at the moment, the scutellaria baicalensis is propped by the limiting cylinder 429 to be suspended, then the four groups of first electric push rods 404 drive the first connecting plate 405 to move downwards and contact with the upper part of the impurity removing hopper 401, so that a closed space is formed, at the moment, bristles below the bristle plate 412 are fully contacted with the scutellaria baicalensis, further, an output shaft of the first motor 406 drives the disc 407 to rotate eccentrically, the disc 407 discontinuously drives the push plate 408 to move towards the hole digging plate 411, the spring 410 rebounds to drive the push plate 408 to return to the original position, so that the push plate 408 is driven to move back and forth, in the process, the polished rod 409 slides back and forth in the hole digging plate 411, further, the push plate 408 drives the bristle plate 412 to move back and forth, meanwhile, the bristle plate 412 utilizes bristles to scrub the scutellaria baicalensis below the bristles to separate dust, debris and other impurities on the outer surface of the scutellaria baicalensis, and then the impurities fall down to the bottom of the impurity removing hopper 401, so that sundries are separated from scutellaria baicalensis, meanwhile, in the process of brushing scutellaria baicalensis by reciprocating movement of the bristle plate 412, the air supply box 420 continuously supplies air to a closed space formed by the impurity removal hopper 401 and the first connecting plate 405, and then the sundries falling at the bottom of the impurity removal hopper 401 are transferred to the second collection box 414 to be collected, and meanwhile, the scutellaria baicalensis is also driven to turn over, so that the sundries on the surface of the bristle plate 412 can be removed by the bristle plate 412, further, after the impurity removal is completed, the bristle plate 412 and the air supply box 420 stop working, the two groups of first electric slide rails 415 drive the two groups of first electric slide blocks 416 to move downwards, and further, the first connecting frame 417 drives the isolation baffle 418 to move downwards, so as to block the opening of the second collection box 414, and meanwhile, the two groups of second electric slide rails 421 drive the two groups of second electric slide blocks 422 to move downwards, and further drives the first L-shaped baffle 424 to move downwards, thereby opening the opening of the lower part of the side of the impurity removing hopper 401 close to the air supply box 420, simultaneously, the four groups of third electric slide rails 425 drive the four groups of L-shaped connecting plates 427 to move downwards through the four groups of third electric slide blocks 426, further drive the fourth connecting plates 428 to move downwards, then the fourth connecting plates 428 drive the limiting cylinders 429 to move downwards, so that the tops of the limiting cylinders 429 and the bottom surfaces of the impurity removing hoppers 401 are at the same height, further, suspended scutellaria baicalensis fall downwards at the bottoms of the impurity removing hoppers 401, further, the two groups of cylinders 403 drive the side of the impurity removing hoppers 401 connected with the impurity removing hoppers to move upwards, further, the impurity removing hoppers 401 are integrally inclined, cleaned scutellaria baicalensis in the impurity removing hoppers 401 are poured into the crushing system 5, and at the moment, the scutellaria baicalensis all slide into the crushing system 5 through the inclined upper surfaces of the first L-shaped baffles 424, the system realizes the anhydrous removal of impurities on the surfaces of the scutellaria baicalensis, and simultaneously collects the separated impurities, avoid debris and the contact of scutellaria baicalensis to cause secondary pollution, then can transfer the scutellaria baicalensis to the crushing system 5 through the inclined impurity removal hopper 401.

The crushing system 5 comprises a bracket 501, a first driving wheel 502, a first rotating rod 503, a second driving wheel 504, a third driving wheel 505, a round roller 506, an arc-shaped cutter 507, a round table 508, a sawtooth plate 509, a grinding column 510, a second electric push rod 511, a second L-shaped baffle 512, an air inlet pipe 513, a feeding port 514, a grinding cabin 515 and a first connecting pipe 516; the bracket 501 is fixedly connected with the support frame 1; the first driving wheel 502 is connected to the mixing system 6; the bracket 501 is rotatably connected with the first rotating rod 503; the first rotating rod 503 is fixedly connected with the first driving wheel 502 and the second driving wheel 504 in sequence; the outer annular surface of the second transmission wheel 504 is in transmission connection with a third transmission wheel 505 through a belt; the third driving wheel 505 is fixedly connected with the round roller 506; four groups of arc-shaped cutters 507 are arranged on the outer surface of the round roller 506; the lower part of the round roller 506 is fixedly connected with a round table 508; the outer surface of the circular truncated cone 508 is fixedly connected with fifteen groups of sawtooth plates 509 in sequence; the lower part of the circular truncated cone 508 is fixedly connected with a grinding column 510; one side of the second electric push rod 511 is fixedly connected with the bracket 501, and the other side of the second electric push rod 511 is fixedly connected with the second L-shaped baffle 512; the second L-shaped baffle 512 is fixedly connected with the air inlet pipe 513; the second L-shaped baffle 512 is contacted with the feed port 514; the lower part of the feed port 514 is fixedly connected with a grinding cabin 515, the grinding cabin 515 is rotatably connected with the round roller 506, and the lower part of the grinding cabin 515 is fixedly connected with the support frame 1; the grinding capsule 515 is solidly connected to a first connection tube 516, and the first connection tube 516 is connected to the mixing system 6.

When the device is used, the air inlet pipe 513 is externally connected with an air blower, the scutellaria baicalensis after being purified by the impurity removing system 4 falls into the grinding chamber 515 through the feed inlet 514, the second L-shaped baffle 512 can block the scutellaria baicalensis to enable the scutellaria baicalensis to be completely transferred into the feed inlet 514, then the second electric push rod 511 drives the second L-shaped baffle 512 to move towards the feed inlet 514, the second L-shaped baffle 512 blocks an opening above the feed inlet 514, the grinding chamber 515 becomes a closed space, then the mixing system 6 drives the first driving wheel 502 to rotate, the first driving wheel 502 drives the second driving wheel 504 to rotate through the first rotating rod 503, the outer annular surface of the second driving wheel 504 drives the third driving wheel 505 to rotate through a belt, the third driving wheel 505 drives the four groups of arc-shaped cutters 507 to rotate through the round rollers 506, so that the scutellaria baicalensis is cut into slices, and further, the sliced scutellaria baicalensis falls downwards into the rotating range of the serrated plate 509, at the moment, the round roller 506 drives the fifteen groups of sawtooth plates 509 to rotate through the round platform 508, then the sawtooth plates 509 stir the flaky scutellaria baicalensis into particles, then the particle scutellaria baicalensis continuously move downwards to a position between the grinding column 510 and the grinding cabin 515, at the moment, the round platform 508 drives the grinding column 510 to rotate, and then the scutellaria baicalensis is ground into powder by matching with the inner wall of the grinding cabin 515, further, while finely crushing the scutellaria baicalensis, an external air blower continuously supplies air to the grinding cabin 515 through the air inlet pipe 513, so that the pulverized scutellaria baicalensis is transferred into the first connection pipe 516, and is further transferred into the mixing system 6 through the first connection pipe 516, in the process, the wind sent by the non-powder scutellaria baicalensis blower cannot transfer the scutellaria baicalensis, and then the scutellaria baicalensis is continuously ground in the working range of the grinding column 510 until the requirements are met, the system realizes multi-stage grinding of the scutellaria baicalensis, and simultaneously can realize only transferring the powder scutellaria baicalensis.

The mixing system 6 comprises a second motor 601, a fourth driving wheel 602, a fifth driving wheel 603, a sixth driving wheel 604, an expansion rod 605, a seventh driving wheel 606, a fifth connecting plate 607, a third electric push rod 608, a fourth electric push rod 609, an eighth driving wheel 610, a second rotating rod 611, a mixing chamber 612, a water inlet 613, a hollow block 614, a second connecting pipe 615, a water pump 616, a third connecting pipe 617, a C-shaped plate 618, a shifting plate 619 and a filter screen 620; the second motor 601 is connected with the support frame 1; an output shaft of the second motor 601 is fixedly connected with a fourth driving wheel 602 and a fifth driving wheel 603 in sequence; the outer ring surface of the fifth driving wheel 603 is in driving connection with the first driving wheel 502 through a belt; the outer annular surface of the fourth driving wheel 602 is in transmission connection with a sixth driving wheel 604 through a belt; the sixth driving wheel 604 is fixedly connected with an expansion link 605, and the expansion link 605 is rotatably connected with the support frame 1; the telescopic rod 605 is fixedly connected with the seventh driving wheel 606; the outer surface of the telescopic rod 605 is rotatably connected with the fifth connecting plate 607; two sides below the fifth connecting plate 607 are fixedly connected with a third electric push rod 608 and a fourth electric push rod 609 in sequence, and the lower sides of the third electric push rod 608 and the fourth electric push rod 609 are fixedly connected with the support frame 1; the outer annular surface of the seventh driving wheel 606 is in transmission connection with an eighth driving wheel 610 through a belt; the eighth transmission wheel 610 is fixedly connected with the second rotating rod 611, and the second rotating rod 611 is rotatably connected with the fifth connecting plate 607; the second rotating rod 611 is slidably connected with the mixing cabin 612, the lower part of the mixing cabin 612 is fixedly connected with the support frame 1, and the mixing cabin 612 is connected with the first connecting pipe 516; the upper part of the mixing cabin 612 is fixedly connected with a water inlet 613; the side surface of the mixing cabin 612 is fixedly connected with the hollow block 614; the hollow block 614 is fixedly connected with the second connecting pipe 615; the second connecting pipe 615 is fixedly connected with a water pump 616, and the water pump 616 is in bolt connection with the support frame 1; the water pump 616 is fixedly connected with a third connecting pipe 617, and the third connecting pipe 617 is fixedly connected with the first collecting tank 2; the lower part of the second rotating rod 611 is fixedly connected with the C-shaped plate 618; two sides of the C-shaped plate 618 are fixedly connected with two groups of shifting plates 619 respectively; the lower portion of the C-shaped plate 618 is fixedly connected with a filter screen 620, and the outer surface of the filter screen 620 is in contact with the interior of the mixing chamber 612.

When the device is used, a water source is externally connected to the water inlet 613, then a nozzle which is not connected with the first connecting pipe 516 is injected into the mixing chamber 612 through the water inlet 613, then when the powdery scutellaria baicalensis is transferred to the mixing chamber 612 through the first connecting pipe 516, the scutellaria baicalensis is fully contacted with water first, so that preliminary mixing is realized, further, the output shaft of the second motor 601 drives the fourth driving wheel 602 and the fifth driving wheel 603 to rotate, when the fifth driving wheel 603 rotates, the first driving wheel 502 rotates through a belt, when the fourth driving wheel 602 rotates, the sixth driving wheel 604 rotates through a belt, further, the sixth driving wheel 604 drives the seventh driving wheel 606 to rotate through the telescopic rod 605, further, the outer annular surface of the seventh driving wheel 606 drives the eighth driving wheel 610 to rotate through a belt, the eighth driving wheel 610 drives the C618 template to rotate through the second rotating rod 611, when the C template 618 rotates, the two groups of shifting plates 619 and the filter screen 620 are driven to rotate, in the process, the C-shaped plate 618 and the two groups of shifting plates 619 continuously stir water, so that the scutellaria baicalensis powder is fully contacted with the water, meanwhile, the rotating filter screen 620 can prevent the scutellaria baicalensis powder from sinking to the bottom, and further, the scutellaria baicalensis powder is stuck to the bottom of the mixing cabin 612 and cannot be mixed with the water, after the scutellaria baicalensis powder is completely added, an external heating device is used for heating the mixing cabin 612, and further, the mixed liquid of the scutellaria baicalensis powder and the water in the mixing cabin 612 is heated to realize a decoction process, during the decoction, the second motor 601 always works, so that the effective components of the scutellaria baicalensis can be fully dissolved in the water, further, after the decoction is finished, the heating is stopped, the second motor 601 stops working, the mixed liquid stands, and then the obtained decoction can be transferred into the hollow block 614, further, the water pump 616 slowly extracts the decoction in the hollow block 614 through the second connecting pipe 615 and transfers the decoction into the first collecting box 2 through the third connecting pipe 617 for collection, then, after all the decoction is transferred, the third electric push rod 608 and the fourth electric push rod 609 move upwards to drive the filter screen 620 to move upwards, so that the scutellaria baicalensis powder residues which are settled for a period of time are driven upwards, water is injected into the mixing chamber 612 through the water inlet 613 again, the scutellaria baicalensis residues are fully contacted with the water, then the filter screen 620 is driven to return to the initial position, the decocting process is repeated twice again, and the decoction obtained by the secondary decocting and the decoction obtained by the third decocting are transferred into the first collecting box 2.

An air outlet is arranged at one side of the air supply box 420 close to the second collection box 414, and the air supply direction of the air outlet is inclined downwards.

The sundries falling from the bottom of the impurity removing hopper 401 can be transferred to the second collecting box 414 to be collected.

The first L-shaped baffle 424 is composed of a vertical plate and a sloping plate.

The vertical plate blocks the opening on one side of the impurity removing hopper 401, and the inclined plate can play a guiding role to guide the scutellaria baicalensis to be transferred to the crushing system 5.

An arc transition is arranged above the limiting cylinder 429.

Can avoid scraping the scutellaria root.

When viewed from above, four groups of arc-shaped cutters 507 are fixedly connected to the outer surface of the round roller 506 in a surrounding manner, wherein two groups of arc-shaped cutters 507 are fixedly connected to the upper half part of the round roller 506, and the other two groups of arc-shaped cutters 507 are fixedly connected to the lower half part of the round roller 506.

When the scutellaria baicalensis falls down to the working range of the arc-shaped cutter 507, the scutellaria baicalensis is cut twice by the upper and lower arc-shaped cutters 507, so that part of the scutellaria baicalensis is prevented from being cut.

The hollow block 614 is provided with a screen 620 on a side adjacent to the mixing chamber 612.

The scutellaria residue is filtered off so that only the decoction can be transferred to the hollow block 614.

A stirring type scutellaria baicalensis decocting method capable of realizing anhydrous impurity removal comprises the following working steps:

the method comprises the following steps: impurity removal, namely putting the scutellaria baicalensis into an impurity removal system 4, separating impurities by brushing the surface of the scutellaria baicalensis in a closed space, and discharging and collecting the impurities separated from the surface of the scutellaria baicalensis by blowing;

step two: transferring, namely transferring the scutellaria baicalensis into a crushing system 5 through an inclined impurity removal system 4;

step three: crushing, wherein the crushing system 5 performs multi-stage crushing on the scutellaria baicalensis to obtain scutellaria baicalensis powder;

step four: transferring, namely transferring the scutellaria baicalensis powder in the step III into a mixing system 6;

step five: mixing, namely adding water into the mixing system 6 and stirring to obtain a mixed solution;

step six: decocting, namely heating the mixed liquid in the fifth step to obtain a decoction;

step seven: separating and transferring, namely filtering the decoction in the step six, transferring the decoction into the first collecting box 2 for collection, and only remaining scutellaria residues in the mixing system 6;

step eight: stirring, wherein the mixing system 6 stirs the residual scutellaria residue in the seventh step;

step nine: and (3) carrying out secondary decoction and tertiary decoction, repeating the steps from five to eight twice, and meanwhile, fully mixing the decoction obtained by the primary decoction, the decoction obtained by the secondary decoction and the decoction obtained by the tertiary decoction in the first collection box 2 to obtain a mixed decoction.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (10)

1. A stirring type scutellaria baicalensis decocting device capable of realizing anhydrous impurity removal comprises a support frame, a first collecting box and a control screen; the method is characterized in that: also comprises an impurity removal system, a crushing system and a mixing system; the supporting frame is connected with the first collecting box; the support frame is connected with an impurity removal system; the support frame is connected with the crushing system; the support frame is connected with a mixing system, and the mixing system is connected with a crushing system; the first collecting box is connected with the control screen.

2. The stirring type scutellaria baicalensis decocting equipment capable of realizing anhydrous impurity removal according to claim 1, wherein the impurity removal system comprises an impurity removal hopper, a connecting rod, a cylinder, a first electric push rod, a first connecting plate, a first motor, a disc, a push plate, a polished rod, a spring, an orifice plate, a bristle plate, a second connecting plate, a second collecting box, a first electric slide rail, a first electric slide block, a first connecting frame, an isolation baffle, a third connecting plate, an air supply box, a second electric slide rail, a second electric slide block, a second connecting frame, a first L-shaped baffle, a third electric slide rail, a third electric slide block, an L-shaped connecting plate, a fourth connecting plate and a limiting cylinder; two sides of the impurity removing hopper are respectively hinged with the two groups of connecting rods, and the lower parts of the two groups of connecting rods are fixedly connected with the supporting frame; two sides of the impurity removing hopper are respectively hinged with the two groups of cylinders, and the lower parts of the two groups of cylinders are hinged with the supporting frame; the impurity removing hopper is fixedly connected with the four groups of first electric push rods in sequence; the four groups of first electric push rods are respectively positioned in four directions of the impurity removing hopper; the four groups of first electric push rods are fixedly connected with the first connecting plate in sequence; the first connecting plate is connected with a first motor; the output shaft of the first motor is fixedly connected with the disc; the disc is contacted with the push plate; the side surface of the push plate is fixedly connected with the polish rod; the lower part of the push plate is fixedly connected with the bristle plate; a spring is arranged on the outer side of the polish rod and fixedly connected with the push plate; the spring is fixedly connected with the hole digging plate, the upper part of the hole digging plate is fixedly connected with the first connecting plate, and the hole digging plate is in sliding connection with the polish rod; the brushing plate is positioned above the impurity removing hopper; one side of the impurity removing hopper is connected with the two groups of second connecting plates through bolts; the other side of the impurity removing hopper is connected with two groups of third connecting plates through bolts; the two groups of second connecting plates are respectively in bolted connection with two sides of the second collecting box, and the second collecting box is in mutual contact with the impurity removing hopper; two groups of first electric slide rails are fixedly connected with two sides of the impurity removing hopper respectively; the two groups of first electric slide rails are respectively connected with the two groups of first electric slide blocks in a sliding manner; two groups of first electric slide blocks are fixedly connected with two sides of the first connecting frame respectively; the first connecting frame is in bolted connection with the isolating baffle, and the isolating baffle is in sliding connection with the impurity removing hopper; the two groups of third connecting plates are fixedly connected with two sides of the air supply box respectively, and the air supply box is in contact with the impurity removal hopper; two groups of second electric slide rails are fixedly connected with two sides of the impurity removing hopper respectively; the two groups of second electric slide rails are sequentially in sliding connection with the two groups of second electric slide blocks; two groups of second electric sliding blocks are fixedly connected with two sides of the second connecting frame respectively; the second connecting frame is in bolted connection with the first L-shaped baffle, and the first L-shaped baffle is in sliding connection with the impurity removing hopper; the third electric slide rail is fixedly connected with the side surface of the impurity removing hopper; the third electric slide rail is in sliding connection with the third electric slide block; the third electric sliding block is fixedly connected with the L-shaped connecting plate; four groups of third electric sliding rails, third electric sliding blocks and L-shaped connecting plates are arranged, and the four groups of third electric sliding rails, the four groups of third electric sliding blocks and the four groups of L-shaped connecting plates are respectively positioned in four directions of the impurity removing hopper; the four groups of L-shaped connecting plates are sequentially connected with four corners below the fourth connecting plate through bolts; and the upper part of the fourth connecting plate is fixedly connected with the limiting cylinder, and the limiting cylinder is spliced with the impurity removing hopper.

3. The stirring type scutellaria baicalensis decocting equipment capable of removing impurities without water according to claim 2, wherein the crushing system comprises a bracket, a first driving wheel, a first rotating rod, a second driving wheel, a third driving wheel, a round roller, an arc-shaped cutter, a round table, a saw-toothed plate, a grinding column, a second electric push rod, a second L-shaped baffle, an air inlet pipe, a feeding hole, a grinding chamber and a first connecting pipe; the bracket is fixedly connected with the support frame; the first driving wheel is connected with the mixing system; the bracket is rotationally connected with the first rotating rod; the first rotating rod is fixedly connected with the first driving wheel and the second driving wheel in sequence; the outer ring surface of the second driving wheel is in transmission connection with a third driving wheel through a belt; the third driving wheel is fixedly connected with the round roller; four groups of arc-shaped cutters are arranged on the outer surface of the round roller; the lower part of the round roller is fixedly connected with the round table; the outer surface of the circular truncated cone is fixedly connected with fifteen groups of sawtooth plates in sequence; the lower part of the circular truncated cone is fixedly connected with the grinding column; one side of the second electric push rod is fixedly connected with the bracket, and the other side of the second electric push rod is fixedly connected with the second L-shaped baffle; the second L-shaped baffle is fixedly connected with the air inlet pipe; the second L-shaped baffle is contacted with the feed inlet; the lower part of the feeding hole is fixedly connected with the grinding cabin, the grinding cabin is rotatably connected with the round roller, and the lower part of the grinding cabin is fixedly connected with the support frame; the grinding cabin is fixedly connected with a first connecting pipe, and the first connecting pipe is connected with the mixing system.

4. The stirring type scutellaria baicalensis decocting equipment capable of realizing anhydrous impurity removal according to claim 3, wherein the mixing system comprises a second motor, a fourth driving wheel, a fifth driving wheel, a sixth driving wheel, a telescopic rod, a seventh driving wheel, a fifth connecting plate, a third electric push rod, a fourth electric push rod, an eighth driving wheel, a second rotating rod, a mixing cabin, a water inlet, a hollow block, a second connecting pipe, a water pump, a third connecting pipe, a C-shaped plate, a shifting plate and a filter screen; the second motor is connected with the support frame; an output shaft of the second motor is fixedly connected with the fourth driving wheel and the fifth driving wheel in sequence; the outer ring surface of the fifth driving wheel is in transmission connection with the first driving wheel through a belt; the outer ring surface of the fourth driving wheel is in transmission connection with the sixth driving wheel through a belt; the sixth driving wheel is fixedly connected with the telescopic rod, and the telescopic rod is rotatably connected with the support frame; the telescopic rod is fixedly connected with the seventh driving wheel; the outer surface of the telescopic rod is rotatably connected with the fifth connecting plate; two sides below the fifth connecting plate are fixedly connected with the third electric push rod and the fourth electric push rod in sequence, and the lower parts of the third electric push rod and the fourth electric push rod are fixedly connected with the supporting frame; the outer ring surface of the seventh driving wheel is in transmission connection with the eighth driving wheel through a belt; the eighth transmission wheel is fixedly connected with the second rotating rod, and the second rotating rod is rotatably connected with the fifth connecting plate; the second rotating rod is connected with the mixing cabin in a sliding mode, the lower portion of the mixing cabin is fixedly connected with the supporting frame, and the mixing cabin is connected with the first connecting pipe; the upper part of the mixing cabin is fixedly connected with the water inlet; the side surface of the mixing cabin is fixedly connected with the hollow block; the hollow block is fixedly connected with the second connecting pipe; the second connecting pipe is fixedly connected with the water pump, and the water pump is connected with the support frame through bolts; the water pump is fixedly connected with the third connecting pipe, and the third connecting pipe is fixedly connected with the first collecting box; the lower part of the second rotating rod is fixedly connected with the C-shaped plate; two sides of the C-shaped plate are fixedly connected with the two groups of shifting plates respectively; the lower part of the C-shaped plate is fixedly connected with the filter screen, and the outer surface of the filter screen is contacted with the interior of the mixing cabin.

5. The stirring type scutellaria baicalensis decocting device capable of removing impurities without water according to claim 4, wherein an air outlet is formed in one side of the air supply box close to the second collecting box, and the air supply direction of the air outlet is inclined downwards.

6. The stirring-type scutellaria baicalensis decocting equipment capable of removing impurities without water according to claim 5, wherein the first L-shaped baffle plate is composed of a vertical plate and an inclined plate.

7. The stirring-type scutellaria baicalensis decocting device capable of removing impurities without water according to claim 6, wherein an arc transition is arranged above the limiting cylinder.

8. An agitation type Scutellariae radix decocting apparatus capable of removing impurities without water as claimed in claim 7, wherein four sets of arc-shaped cutters are fixedly connected around the outer surface of the roller, two sets of arc-shaped cutters are fixedly connected to the upper half of the roller, and the other two sets of arc-shaped cutters are fixedly connected to the lower half of the roller.

9. The stirring-type scutellaria baicalensis decocting apparatus capable of removing impurities without water according to claim 8, wherein a filter screen is arranged on one side of the hollow block close to the mixing chamber.

10. A stirring type scutellaria baicalensis decocting method capable of realizing anhydrous impurity removal is characterized by comprising the following working steps:

the method comprises the following steps: impurity removal, namely putting the scutellaria baicalensis into an impurity removal system, scrubbing the surface of the scutellaria baicalensis in a closed space to separate impurities, and simultaneously blowing air to discharge and collect the impurities separated from the surface of the scutellaria baicalensis;

step two: transferring, namely transferring the scutellaria baicalensis into a crushing system through an inclined impurity removal system;

step three: crushing, and performing multistage crushing on the scutellaria baicalensis by a crushing system to obtain scutellaria baicalensis powder;

step four: transferring, namely transferring the scutellaria baicalensis powder in the step III into a mixing system;

step five: mixing, namely adding water into a mixing system and stirring to obtain a mixed solution;

step six: decocting, namely heating the mixed liquid in the fifth step to obtain a decoction;

step seven: separating and transferring, namely filtering the decoction in the step six, transferring the decoction into a first collecting box for collection, and only remaining scutellaria residues in a mixing system;

step eight: stirring, namely stirring the residual scutellaria baicalensis residue in the seventh step by a mixing system;

step nine: and (3) carrying out secondary decoction and tertiary decoction, repeating the step five to the step eight twice, and meanwhile, fully mixing the decoction obtained by the primary decoction, the decoction obtained by the secondary decoction and the decoction obtained by the tertiary decoction in a first collection box to obtain a mixed decoction.

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